EeroQ has successfully demonstrated the controlled transport of electrons on superfluid helium using a commercial silicon control architecture, paving the way for all-to-all qubit routing. This breakthrough, published in Physical Review Applied, showcases the feasibility of using CMOS-controlled electron shuttling to enable scalable quantum computing. The experimental results highlight the selective, two-dimensional transport of electrons, validating the structural integrity of EeroQ's Wonder Lake chip stack. This achievement has significant implications for the development of quantum hardware, as it enables the creation of more complex quantum systems with increased connectivity. The use of a commercial silicon control platform also suggests a potential path towards more widespread adoption of quantum technologies1. This development matters to practitioners because it brings quantum computing one step closer to realizing its full potential, which could fundamentally change the landscape of computation and cryptography.
EeroQ Validates CMOS-Controlled Electron Shuttling on Superfluid Helium for All-to-All Qubit Routing
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Why This Matters
Quantum computing developments are rewriting assumptions about computation and cryptography.
References
- Quantum Computing Report. (2026, July 11). EeroQ Validates CMOS-Controlled Electron Shuttling on Superfluid Helium for All-to-All Qubit Routing. *Quantum Computing Report*. https://quantumcomputingreport.com/eeroq-validates-cmos-controlled-electron-shuttling-on-superfluid-helium-for-all-to-all-qubit-routing/
Original Source
Quantum Computing Report
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